We’re committed to improving our ecosystems, quality of life, and communities for the better.
Our passion and commitment to the integration of innovative science and engineering drive us to exceed on behalf of every client.
WP_Query Object ( [query] => Array ( [tag] => engineering ) [query_vars] => Array ( [tag] => engineering [error] => [m] => [p] => 0 [post_parent] => [subpost] => [subpost_id] => [attachment] => [attachment_id] => 0 [name] => [pagename] => [page_id] => 0 [second] => [minute] => [hour] => [day] => 0 [monthnum] => 0 [year] => 0 [w] => 0 [category_name] => stream_restoration [cat] => 41 [tag_id] => 369 [author] => [author_name] => [feed] => [tb] => [paged] => 1 [meta_key] => [meta_value] => [preview] => [s] => [sentence] => [title] => [fields] => all [menu_order] => [embed] => [category__in] => Array ( [0] => 41 ) [category__not_in] => Array ( ) [category__and] => Array ( ) [post__in] => Array ( ) [post__not_in] => Array ( ) [post_name__in] => Array ( ) [tag__in] => Array ( ) [tag__not_in] => Array ( ) [tag__and] => Array ( ) [tag_slug__in] => Array ( [0] => engineering ) [tag_slug__and] => Array ( ) [post_parent__in] => Array ( ) [post_parent__not_in] => Array ( ) [author__in] => Array ( ) [author__not_in] => Array ( ) [search_columns] => Array ( ) [ignore_sticky_posts] => [suppress_filters] => [cache_results] => 1 [update_post_term_cache] => 1 [update_menu_item_cache] => [lazy_load_term_meta] => 1 [update_post_meta_cache] => 1 [post_type] => [posts_per_page] => 10 [nopaging] => [comments_per_page] => 5 [no_found_rows] => [order] => DESC ) [tax_query] => WP_Tax_Query Object ( [queries] => Array ( [0] => Array ( [taxonomy] => category [terms] => Array ( [0] => 41 ) [field] => term_id [operator] => IN [include_children] => ) [1] => Array ( [taxonomy] => post_tag [terms] => Array ( [0] => engineering ) [field] => slug [operator] => IN [include_children] => 1 ) ) [relation] => AND [table_aliases:protected] => Array ( [0] => ph_term_relationships [1] => tt1 ) [queried_terms] => Array ( [category] => Array ( [terms] => Array ( [0] => 41 ) [field] => term_id ) [post_tag] => Array ( [terms] => Array ( [0] => engineering ) [field] => slug ) ) [primary_table] => ph_posts [primary_id_column] => ID ) [meta_query] => WP_Meta_Query Object ( [queries] => Array ( ) [relation] => [meta_table] => [meta_id_column] => [primary_table] => [primary_id_column] => [table_aliases:protected] => Array ( ) [clauses:protected] => Array ( ) [has_or_relation:protected] => ) [date_query] => [queried_object] => WP_Term Object ( [term_id] => 369 [name] => engineering [slug] => engineering [term_group] => 0 [term_taxonomy_id] => 369 [taxonomy] => post_tag [description] => [parent] => 0 [count] => 79 [filter] => raw [term_order] => 0 ) [queried_object_id] => 369 [request] => SELECT SQL_CALC_FOUND_ROWS ph_posts.ID FROM ph_posts LEFT JOIN ph_term_relationships ON (ph_posts.ID = ph_term_relationships.object_id) LEFT JOIN ph_term_relationships AS tt1 ON (ph_posts.ID = tt1.object_id) WHERE 1=1 AND ( ph_term_relationships.term_taxonomy_id IN (41) AND tt1.term_taxonomy_id IN (369) ) AND ((ph_posts.post_type = 'post' AND (ph_posts.post_status = 'publish' OR ph_posts.post_status = 'acf-disabled'))) GROUP BY ph_posts.ID ORDER BY ph_posts.menu_order, ph_posts.post_date DESC LIMIT 0, 10 [posts] => Array ( [0] => WP_Post Object ( [ID] => 19057 [post_author] => 1 [post_date] => 2026-01-28 15:50:41 [post_date_gmt] => 2026-01-28 15:50:41 [post_content] => More than a century after the Paulina Lake Dam first altered the Paulins Kill River, the site now tells a very different story. A recent return visit confirms what restoration practitioners know well: when barriers are removed, rivers heal. Today, the Paulins Kill flows freely through the former Paulina Lake Dam site, reconnecting habitats that had been fragmented for generations. The Paulina Lake Dam stood for nearly 130 years in Blairstown Township, Warren County, NJ. Constructed in the late 1800s to generate hydropower, it had long outlived its original purpose. Like many aging dams across the country, it remained in place despite no longer serving a critical function, while continuing to disrupt river processes and pose growing safety risks. [caption id="attachment_19094" align="aligncenter" width="800"] Paulina Lake Dam aerial view prior to removal. Photo by Jim Wright/TNC/LightHawk[/caption] As reported in CentralJersey.com’s recent feature “The fall of dams and rise of rivers,” the majority of New Jersey’s approximately 1,700 regulated dams were built in the 19th and early 20th centuries to power mills that no longer exist. Fewer than a dozen still serve an essential purpose today. Many persist due to nostalgia, misunderstanding, or uncertainty around removal—despite blocking fish passage, trapping sediment, warming water temperatures, exacerbating flooding, and increasing the risk of failure. The removal of Paulina Lake Dam was led by The Nature Conservancy (TNC) in partnership with Blairstown Township, New Jersey Department of Environmental Protection, U.S. Fish and Wildlife Service, Riverlogic–Renova Joint Venture, and Princeton Hydro. The Office of Natural Resources Revenue awarded a grant to TNC to fund a substantial portion of the removal through the Paulins Kill and Pequest Watershed Natural Resource Restoration Grant Program. The project advanced through carefully sequenced phases, beginning with controlled notching in late 2023, followed by full demolition and sediment management in 2024, and transitioning into final adaptive management and habitat enhancement in 2025. What the River is Showing Us Now The ecological response has been swift and visible. With the dam removed, more than 7.6 miles of mainstem and tributary habitat have been reconnected at the Paulina Lake site alone. The removal of the Paulina Lake Dam represents one important element of a longer-term, watershed-scale restoration initiative launched in 2013 to restore connectivity and ecological function along the Paulins Kill River. As the downstream most dam on the river, its removal builds upon earlier restoration milestones achieved through the removal of four dams: the Columbia Lake Main and Remnant Dams in 2019, the County Line Dam in 2021, and now the Paulina Lake Dam, progressively reconnecting approximately 45 miles of mainstem and tributary habitat. Since 2016, The Nature Conservancy has also implemented a 10-year Measures and Monitoring Program to track ecological response and conservation outcomes, providing clear evidence that coordinated, science-based restoration can support a healthier, more resilient river system. The river channel is actively stabilizing, riffle and run sequences are re-forming, and previously inundated areas are beginning to revegetate. Cooler water temperatures and the restoration of sediment transport processes are enabling the Paulins Kill to function more consistently with a cold, free‑flowing, coarse‑substrate stream system. This series of aerial drone photos was captured during a site visit in November 2025: [gallery link="none" size="medium" ids="19109,19110,19111"] This recovery is already benefiting aquatic life. As Beth Styler Barry, Director of Freshwater Programs for The Nature Conservancy in New Jersey, noted in the CentralJersey.com article, “We’re already seeing American shad above the dams that were removed. We’re seeing sea lamprey and American eel. It used to be that only the biggest eels could make it upstream. Now we’re seeing all age classes.” By reconnecting upstream and downstream populations that had been isolated for generations, the project has also restored connectivity for rare freshwater mussels, including the endangered dwarf wedgemussel (Alasmidonta heterodon) and triangle floater (Alasmidonta undulata). “All of the organisms in a river like the Paulins Kill evolved to live in a cool, flowing, rocky-bottom stream,” Styler Barry told CentralJersey.com. “When you restore flow, the river begins to heal itself.” Watch the Project from Start to Finish A newly released project video captures this transformation in a way that still images and written updates cannot. Drawing on aerial footage collected by The Nature Conservancy’s Volunteer Drone Team prior to demolition and by Princeton Hydro throughout and after construction, the video documents the full arc of the Paulina Lake Dam removal from initial notching through full demolition and into the restored conditions visible today. The footage provides a comprehensive look at dam removal in practice, illustrating how careful sequencing, sediment management, and adaptive design allow rivers to recover rapidly once barriers are removed. Click below to watch the full project video and see the transformation unfold: [embed]https://www.youtube.com/watch?v=T6dQRRU5DCE[/embed] Beyond ecological gains, the removal of Paulina Lake Dam has significantly improved public safety and community resilience. In CentralJersey.com, Geoffrey M. Goll, PE, President of Princeton Hydro, emphasized the long-term risks associated with aging dams. “If you don’t take care of them, they’ll come out on their own—and that’s a much bigger problem. Once dams are properly removed, people start to see the value of a free-flowing river.” Many dams were never designed to withstand today’s hydrologic conditions. With climate change driving more frequent and intense rainfall events, proactive removal reduces flood risk, eliminates inspection and maintenance liabilities, and allows rivers to function as more resilient, self-sustaining systems. At the Paulina Lake site, removal has also improved recreational access and restored a more natural landscape for the community. Looking Ahead While the Paulins Kill now flows freely through the former Paulina Lake Dam site, final project phases focus on adaptive management, targeted bank stabilization, habitat feature enhancement, and native tree planting to support long term ecological resilience. As the river continues to adjust and evolve, the Paulina Lake Dam site stands as a clear example of what is possible when outdated infrastructure is thoughtfully removed and natural systems are given the opportunity to recover. To learn more about TNC's work to restore the Paulins Kill River, click here. To learn more about Princeton Hydro's work to remove dams and restore rivers throughout the Northeast, click here. [post_title] => Then and Now: Paulina Lake Dam Removal [post_excerpt] => [post_status] => publish [comment_status] => open [ping_status] => open [post_password] => [post_name] => then-and-now-paulina-lake-dam-removal [to_ping] => [pinged] => [post_modified] => 2026-01-28 15:59:36 [post_modified_gmt] => 2026-01-28 15:59:36 [post_content_filtered] => [post_parent] => 0 [guid] => https://princetonhydro.com/?p=19057 [menu_order] => 0 [post_type] => post [post_mime_type] => [comment_count] => 0 [filter] => raw ) [1] => WP_Post Object ( [ID] => 15800 [post_author] => 1 [post_date] => 2024-12-04 14:59:57 [post_date_gmt] => 2024-12-04 14:59:57 [post_content] => In urban areas, streams have often been buried beneath streets, buildings, and infrastructure, cutting them off from the natural ecosystem. However, a growing movement towards "daylighting" streams—uncovering and restoring these buried watercourses—has proven to be an innovative solution for improving water quality, reducing flood risks, restoring fish passage, and creating healthier habitats. Princeton Hydro has been at the forefront of these efforts, bringing expertise in ecological restoration and water resource management to daylighting projects across New Jersey. What Exactly is Daylighting? Daylighting is the process of removing obstructions and impervious surfaces from a buried stream or river, restoring it to a more natural state. Often, streams were diverted underground to make way for urban development. Daylighting involves reversing this process, bringing the water flow back above ground where it can interact with the natural environment. The result is a newly visible, revitalized waterway that reconnects the stream to its surrounding ecosystem. This process not only improves stormwater management but also enhances urban spaces and promotes healthier habitats. The Benefits of Daylighting Streams Daylighting streams offers numerous advantages to both the environment and local communities. Some key benefits include:
More than a century after the Paulina Lake Dam first altered the Paulins Kill River, the site now tells a very different story. A recent return visit confirms what restoration practitioners know well: when barriers are removed, rivers heal. Today, the Paulins Kill flows freely through the former Paulina Lake Dam site, reconnecting habitats that had been fragmented for generations.
The Paulina Lake Dam stood for nearly 130 years in Blairstown Township, Warren County, NJ. Constructed in the late 1800s to generate hydropower, it had long outlived its original purpose. Like many aging dams across the country, it remained in place despite no longer serving a critical function, while continuing to disrupt river processes and pose growing safety risks.
As reported in CentralJersey.com’s recent feature “The fall of dams and rise of rivers,” the majority of New Jersey’s approximately 1,700 regulated dams were built in the 19th and early 20th centuries to power mills that no longer exist. Fewer than a dozen still serve an essential purpose today. Many persist due to nostalgia, misunderstanding, or uncertainty around removal—despite blocking fish passage, trapping sediment, warming water temperatures, exacerbating flooding, and increasing the risk of failure.
The removal of Paulina Lake Dam was led by The Nature Conservancy (TNC) in partnership with Blairstown Township, New Jersey Department of Environmental Protection, U.S. Fish and Wildlife Service, Riverlogic–Renova Joint Venture, and Princeton Hydro. The Office of Natural Resources Revenue awarded a grant to TNC to fund a substantial portion of the removal through the Paulins Kill and Pequest Watershed Natural Resource Restoration Grant Program.
The project advanced through carefully sequenced phases, beginning with controlled notching in late 2023, followed by full demolition and sediment management in 2024, and transitioning into final adaptive management and habitat enhancement in 2025.
The ecological response has been swift and visible.
With the dam removed, more than 7.6 miles of mainstem and tributary habitat have been reconnected at the Paulina Lake site alone. The removal of the Paulina Lake Dam represents one important element of a longer-term, watershed-scale restoration initiative launched in 2013 to restore connectivity and ecological function along the Paulins Kill River. As the downstream most dam on the river, its removal builds upon earlier restoration milestones achieved through the removal of four dams: the Columbia Lake Main and Remnant Dams in 2019, the County Line Dam in 2021, and now the Paulina Lake Dam, progressively reconnecting approximately 45 miles of mainstem and tributary habitat.
Since 2016, The Nature Conservancy has also implemented a 10-year Measures and Monitoring Program to track ecological response and conservation outcomes, providing clear evidence that coordinated, science-based restoration can support a healthier, more resilient river system.
The river channel is actively stabilizing, riffle and run sequences are re-forming, and previously inundated areas are beginning to revegetate. Cooler water temperatures and the restoration of sediment transport processes are enabling the Paulins Kill to function more consistently with a cold, free‑flowing, coarse‑substrate stream system.
This recovery is already benefiting aquatic life. As Beth Styler Barry, Director of Freshwater Programs for The Nature Conservancy in New Jersey, noted in the CentralJersey.com article, “We’re already seeing American shad above the dams that were removed. We’re seeing sea lamprey and American eel. It used to be that only the biggest eels could make it upstream. Now we’re seeing all age classes.”
By reconnecting upstream and downstream populations that had been isolated for generations, the project has also restored connectivity for rare freshwater mussels, including the endangered dwarf wedgemussel (Alasmidonta heterodon) and triangle floater (Alasmidonta undulata).
“All of the organisms in a river like the Paulins Kill evolved to live in a cool, flowing, rocky-bottom stream,” Styler Barry told CentralJersey.com. “When you restore flow, the river begins to heal itself.”
A newly released project video captures this transformation in a way that still images and written updates cannot.
Drawing on aerial footage collected by The Nature Conservancy’s Volunteer Drone Team prior to demolition and by Princeton Hydro throughout and after construction, the video documents the full arc of the Paulina Lake Dam removal from initial notching through full demolition and into the restored conditions visible today. The footage provides a comprehensive look at dam removal in practice, illustrating how careful sequencing, sediment management, and adaptive design allow rivers to recover rapidly once barriers are removed.
Beyond ecological gains, the removal of Paulina Lake Dam has significantly improved public safety and community resilience. In CentralJersey.com, Geoffrey M. Goll, PE, President of Princeton Hydro, emphasized the long-term risks associated with aging dams. “If you don’t take care of them, they’ll come out on their own—and that’s a much bigger problem. Once dams are properly removed, people start to see the value of a free-flowing river.”
Many dams were never designed to withstand today’s hydrologic conditions. With climate change driving more frequent and intense rainfall events, proactive removal reduces flood risk, eliminates inspection and maintenance liabilities, and allows rivers to function as more resilient, self-sustaining systems. At the Paulina Lake site, removal has also improved recreational access and restored a more natural landscape for the community.
While the Paulins Kill now flows freely through the former Paulina Lake Dam site, final project phases focus on adaptive management, targeted bank stabilization, habitat feature enhancement, and native tree planting to support long term ecological resilience. As the river continues to adjust and evolve, the Paulina Lake Dam site stands as a clear example of what is possible when outdated infrastructure is thoughtfully removed and natural systems are given the opportunity to recover.
In urban areas, streams have often been buried beneath streets, buildings, and infrastructure, cutting them off from the natural ecosystem. However, a growing movement towards "daylighting" streams—uncovering and restoring these buried watercourses—has proven to be an innovative solution for improving water quality, reducing flood risks, restoring fish passage, and creating healthier habitats. Princeton Hydro has been at the forefront of these efforts, bringing expertise in ecological restoration and water resource management to daylighting projects across New Jersey.
Daylighting is the process of removing obstructions and impervious surfaces from a buried stream or river, restoring it to a more natural state. Often, streams were diverted underground to make way for urban development. Daylighting involves reversing this process, bringing the water flow back above ground where it can interact with the natural environment. The result is a newly visible, revitalized waterway that reconnects the stream to its surrounding ecosystem. This process not only improves stormwater management but also enhances urban spaces and promotes healthier habitats.
Daylighting streams offers numerous advantages to both the environment and local communities. Some key benefits include:
Princeton Hydro has successfully completed numerous daylighting projects that demonstrate the transformative power of restoring natural waterways. By leveraging innovative engineering and ecological practices, these projects restored the natural flow of waterways and enhanced the surrounding landscape. Let’s take a closer look at two examples:
In the heart of Trenton, NJ, Princeton Hydro undertook a comprehensive stream restoration. The City of Trenton, as part of a larger urban revitalization and brownfield redevelopment project, sought to restore the stream, Petty’s Run, which had long suffered from typical urban afflictions: pollution, flooding, and heavy debris accumulation.
Princeton Hydro developed a green infrastructure design that addressed these challenges holistically. The design included removing from the stream channel heavy debris, contaminated soils, and the concrete remains of previous development. The team also replaced the restrictive upstream road crossing with a pedestrian bridge, enhancing both the stream’s flow and the community’s connectivity. A significant aspect of the project involved daylighting the 250-foot underground portion of Petty’s Run, restoring it to a natural, open flow while creating an adjacent floodplain meadow to manage stormwater and provide habitat.
The project improved stormwater management, enhanced the landscape’s biodiversity, added habitat value, and established a new public green space with walking trails, which now serves as both an ecological asset and a recreational area for the community. This project earned both the Phoenix Award for Brownfield Redevelopment and the Bowman’s Hill Land Ethics Award.
Thompson Park, a sprawling 675-acre recreational area in Middlesex County, NJ, boasts a variety of amenities, including hiking trails, ballfields, and a zoo that is home to over 50 geese and fowl, goats, and approximately 90 deer. The streams within the park faced challenges, particularly in the areas surrounding the zoo’s enclosures, including erosion and compromised water quality.
In order to increase channel stability, decrease erosion, improve water quality and ecological function, and reduce the pollutants originating from the zoo, a stormwater management treatment train was designed and constructed.
Middlesex County Office of Parks and Recreation and Office of Planning, New Jersey Department of Environmental Protection, South Jersey Resource Conservation and Development Council, Middlesex County Mosquito Extermination Commission, Freehold Soil Conservation District, Rutgers Cooperative Extension, Enviroscapes and Princeton Hydro worked together to fund, design, permit, and construct numerous stormwater management measures within Thompson Park.
One of the key project initiatives involved daylighting a section of a 24-inch reinforced concrete pipe (RCP) that had previously conveyed stormwater underground. Daylighting the stream, widen the stream channel, improved stormwater absorption, reduced erosion, helped restore the stream’s natural gradient, and improved aquatic habitat.
This multi-faceted restoration project improved stream function and created a more sustainable environment for both zoo inhabitants, the park’s visitors, and the watershed.
Princeton Hydro’s President and Founding Principal, Geoffrey M. Goll, PE, recently shared his expertise in stream restoration during a "Daylighting Streams: Design & Engineering" webinar hosted by The Watershed Institute. The webinar explored the process of uncovering and restoring buried watercourses. Moderated by Susan Bristol, The Watershed Institute Municipal Policy Specialist, the webinar featured experts Vince Sortman, Biohabitats Senior Fluvial Geomorphologist; Warren T. Byrd, Jr., FASLA, Founding Partner of Nelson Byrd Woltz Landscape Architects & Professor Emeritus, University of Virginia; and Geoffrey. The webinar provided valuable insights into the challenges and benefits of these projects, highlighting the importance of hazard mitigation, maintenance, and community involvement in successful daylighting initiatives. The event underscored the significance of daylighting in enhancing both urban infrastructure and natural ecosystems.
Daylighting streams is a forward-thinking approach to urban water management that brings immense benefits to the environment and local communities. As daylighting continues to gain recognition as an essential tool for watershed restoration, Princeton Hydro remains a trusted leader in the field, combining innovative design with environmental stewardship.
Nestled within the New Jersey townships of Hamilton, Robbinsville, and West Windsor lies Miry Run Dam Site 21—an expansive 279-acre parcel with a rich history dating back to its acquisition by Mercer County in the late 1970s. Originally earmarked for flood mitigation and recreation, this hidden gem is on the cusp of a remarkable transformation, poised to unveil its true potential as a thriving public park.
Central to the revitalization efforts is a comprehensive Master Plan, meticulously crafted by Mercer County Park Commission in partnership with Simone Collins Landscape Architecture and Princeton Hydro. This visionary roadmap encompasses a spectrum of engineering and ecological uplift initiatives, including:
The Master Plan serves as a long-term vision for improvements to the property and will be implemented over multiple phases. In 2021, it was recognized with the Landscape Architectural Chapter Award from the New Jersey Chapter American Society of Landscape Architects, which underscores its innovative and impactful approach to landscape design.
Now, Dam Site 21’s revitalization has begun with a crucial endeavor: the dredging of its 50-acre lake. This process, spearheaded by Mercer County Park Commission in collaboration with Princeton Hydro, aims to rejuvenate the water body by removing accumulated debris, sediment, and invasive vegetation—a vital step towards restoring its ecological balance. Beyond the aesthetic and ecological improvements, dredging enhances accessibility for recreational activities that provide an opportunity to create a deeper connection between the park’s visitors and its beautiful natural landscape.
Based on the bathymetric assessment, which the Princeton Hydro team completed as part of the Master Plan, the dredging efforts are focused on three primary areas: Area 1 is located in the main body of the lake just downstream of Line Road and will generate approximately 34,000 cubic yards of dredged material; Area 2, which has approximately 4,900 cubic yards of accumulated sediment is located in the northeast cove, just north of Area 1; and Area 3, the northwestern cove, entails the removal of approximately 7,300 cubic yards of accumulated sediment.
Before the dredging work could begin, the Princeton Hydro team was responsible for providing a sediment sampling plan, sample collection and laboratory analysis, engineering design plan, preparation and submission of all NJDEP regulatory permitting materials, preparation of the technical specifications, and bid administration. Currently, our team is providing construction administration and oversight for the project.
The journey towards Dam Site 21's revival has been marked by meticulous planning, design, and community engagement spanning several years. With the commencement of dredging operations, the project's vision is gradually materializing—a testament to the dedication of all stakeholders involved. As the first phase unfolds, anticipation mounts for the realization of a vibrant, inclusive public space that honors both nature and community.
As Dam Site 21 undergoes its metamorphosis, it symbolizes not just a physical restoration, but a renewal of collective vision and commitment. Ultimately, Dam Site 21 isn't just a park—it's a testament to the enduring legacy of conservation, community, and the transformative power of restoration.
The significance of Dam Site 21's transformation extends far beyond its recreational appeal. It embodies a commitment to environmental stewardship, with measures aimed at bolstering flood resilience, improving water quality, and nurturing diverse wildlife habitats. By blending conservation with recreation, the project strikes an important balance between creating access for community members to enjoy the space and ecological preservation that puts native plants, critical habitat, and wildlife at the forefront.
To learn more about the restoration initiative and view the Final Master Plan, visit the Mercer County Park Commission’s website. Click here to learn about another one of Princeton Hydro’s recent restoration efforts. And, stay tuned here for more Mercer County Park Commission project updates!
In the late 1920s, the U.S. government began allocating funds for road construction in U.S. national forests. This led to hundreds of thousands of culverts being built and installed across the country for the purpose of moving water quickly and efficiently underneath the roadways to prevent flooding, minimize erosion, and provide pathways for stormwater.
However, culverts have had an unintended and significant consequence: they block the migration routes of some fish and aquatic organisms.
Culverts that are undersized, improperly placed, or designed with smooth featureless surfaces can impede or totally block fish and aquatic species from passing. Culverts with extremely high velocity flows make it incredibly difficult for aquatic organisms to navigate upstream, and extremely low velocity flows make it hard for fish to pass in either direction. The high-velocity flows can erode the stream channel immediately downstream of the culvert, which can leave the culvert pipe perched. This elevation above the water channel makes it impossible for organisms to pass through. Debris can also collect in the culvert, not only blocking fish passage, but water as well.
In addition to blocking the upstream passage of fish and other aquatic species, some culverts disrupt the normal stream movements of some macroinvertebrates, which are key components of these stream ecosystems, an important food source to countless species, and play a critical role in the cycling of energy and nutrients throughout stream ecosystems. Disruptions to the movement and dispersal of stream macroinvertebrates can reduce available habitat, lead to genetic isolation of some populations, and cause extirpation of critical species. When populations splinter, it causes a reduction in genetic diversity, which can lead to the spread of more invasive species and many other ecological issues.
While culverts serve an important function in road construction and flood prevention, their impact on aquatic organisms must be taken into consideration. Finding solutions that both allow for efficient water flow and enable safe aquatic migration is crucial in preserving the health of our waterways and their ecosystems.
A shift in the 1980s recognized the importance of redesigning road-stream crossings for several reasons, including restoring aquatic organism passage and maintaining flood resilience. Between 2008 and 2015, U.S. Forest Service (USFS) partnered with more than 200 organizations in the Legacy Roads and Trails Program to replace 1,000+ culverts across the country. The aim of the program was to upgrade culverts to emulate natural streams and to allow fish and wildlife to pass more naturally both upstream and downstream.
Replacing culverts with structures that better facilitate the movement of both water and aquatic organisms has benefits beyond restoring critical ecosystems and improving biodiversity. Ecological restoration creates jobs, stimulates outdoor recreation and local economic activity, and generates long-term economic value.
Princeton Hydro has a strong history in designing connectivity-friendly road-stream crossings and restoring/replacing outdated culverts. Our team of engineers and scientists has been directly involved with hundreds of stream and ecosystem restoration projects throughout the Northeast.
For several years, Princeton Hydro has partnered with NY-NJ Harbor & Estuary Program (HEP) to plan and design for aquatic connectivity through climate-ready infrastructure. Created by the U.S. Environmental Protection Agency (USEPA) at the request of the governors of New York and New Jersey, HEP develops and implements plans that protect, conserve and restore the estuary, and aquatic connectivity is a key focus area for HEP and its partners.
Most recently, HEP partnered with Princeton Hydro to address hydraulic capacity issues at priority road-stream crossings in New Jersey’s South River and Lower Raritan River watersheds. The Princeton Hydro team developed a 30% engineering plan for a priority road-stream crossing – the Birch Street crossing over the Iresick Brook in Old Bridge, NJ.
Iresick Brook is upstream from Duhernal Lake, located at the end of the free-flowing South River, which feeds into the Raritan River, and ultimately flows into Raritan Bay. Duhernal Lake is dammed at the outlet so there is little to no connectivity downstream from the Iresick Brook sub-watershed. The watershed is highly dendritic (meaning the drainage pattern follows a tree-like shape) with many small streams running through it, some of them ephemeral.
The Iresick Brook 5 (IB5) culvert, located in Old Bridge Township, New Jersey, is an undersized double culvert in poor condition with an eroding streambank. This culvert was chosen as a restoration priority primarily due its inadequate sizing (both pipes are only 3-feet in diameter). The outdated infrastructure blocks the passage of fish and other aquatic organisms, and it can only accommodate a 50-year storm event.
Once the IB5 culvert was identified as the priority site, Princeton Hydro completed a site investigation, which included a geomorphic assessment, site observations, and simplified site survey of the channel alignment, profile, and cross sections both upstream and downstream of the culvert.
At the time of the survey, flow was only a couple inches deep in the channel and incredibly slow-moving, especially in the upstream reach. Despite the low flow at the time of the survey, during storm events, the stream experiences extremely high velocities. The undersized culvert creates hydraulic constriction and subsequently a velocity barrier that prevents passage. Additionally, when the high-flow stream water is forced through the small pipes, it creates a firehose effect, which has led to the formation of a 60-foot-long scour hole at the culvert outlet. Substrate from the scour hole has been washed downstream, forming an island of large sand and small gravel.
Approximately 155 feet upstream of the culvert is a channel-spanning v-notch weir comprised of a combination of sheet pile and timber. The weir appears to be a historical stream gauge that is highly degraded and creates an artificially perched channel. The upstream channel also contains woody debris, which gets caught at the culvert, blocking water flow and organism passage.
For the design process, Princeton Hydro used the USFS Stream Simulation Design, an gold-standard ecosystem-based approach for designing and constructing road-stream crossings that provide unimpeded fish and other aquatic organism passage through the structure. The Stream Simulation, a required standard on USFS road projects, integrates fluvial geomorphology concepts and methods with engineering principles to design a road-stream crossing that contains a natural and dynamic channel through the structure so that fish and other aquatic organisms will experience no greater difficulty moving through the structure than if the crossing did not exist.
The design also incorporated utility constraints (gas line, sewer line, drinking water main, and stormwater outlet), a longitudinal profile assessment, channel capacity and slope analysis, and a simplified hydrologic & hydraulic assessment.
Ultimately, Princeton Hydro recommended that HEP replace the existing culvert with a Contech Precast O-321 culvert, or similar alternative. The proposed design increases the culvert opening area and allows for significant increases in flow capacity. This culvert replacement project has the potential to reduce local flood risk and restore aquatic organism passage to the reach of Iresick Brook.
Aquatic connectivity is crucial for improving healthy aquatic ecosystems and managing severe storms and flooding. Increases in rainfall due to climate change makes investing in these improvements even more of a growing priority. With so many culverts in place, it can be difficult to know which culvert restoration projects to prioritize.
We worked with HEP to create a toolkit for addressing problematic road-stream crossings. The easy-to-use matrix helps to prioritize potential projects and identify solutions for problem culverts and relative cost solutions.
The toolkit was just recently released to the public with the hope that it will be used as a template to promote the development of more resilient and environmentally-friendly infrastructure.
Click here to get more info and download.
Aquatic connectivity is crucial for improving healthy aquatic ecosystems and managing severe storms and flooding. Increases in rainfall due to climate change makes investing in these improvements even more of a growing priority. With so many culverts in place – not to mention, many of these culverts are located in river headwaters – it can be very challenging to know which culvert restoration projects to prioritize.
Princeton Hydro partnered with New York - New Jersey Harbor & Estuary Program (HEP) and the Hudson River Foundation to create a toolkit for addressing problematic road-stream crossings. The easy-to-use matrix helps to prioritize potential projects and identify solutions for problem culverts and relative cost solutions.
The toolkit is meant to be used by a wide audience of professionals and volunteers, including those familiar with the North America Aquatic Connectivity Collaborative (NAACC) protocol for assessing road stream crossings. It builds on the data collected through the NAACC (or similar) field assessments to identify the least expensive & highest priority project sites and provide solutions ranging from low-tech solutions that can be implemented by volunteers at minor blockages, to detailed engineering and construction plans that would require qualified contractors to implement at severe blockages.
Read the full description and download the toolkit now by clicking below:
If you've ever observed orange water in a river or stream after a dam has been removed, you may have been surprised by the strange color. This phenomenon is caused by iron oxide floc. But what exactly is iron oxide floc and how does it form?
Iron oxide, also known as rust, is a common compond found in nature. When it is dissolved in water, it takes on a reddish-brown color. Although the color can be alarming, iron oxide floc is relatively harmless and is actually a sign of the waterway returning to a more natural state.
The formation of iron oxide floc begins with the seepage of anaerobic groundwater through the embankment of a dam. The groundwater behind a dam often contains high levels of iron and is anaerobic (low in oxygen) because it is not exposed to the air and therefore does not have access to oxygen. When this anaerobic water reaches the other side of the dam and mixes with the aerobic surface water, the oxygen in the surface water reacts with the iron in the groundwater, forming iron oxide floc.
The orange color of the water is a result of the floc suspending in the water column and/or settling to the bottom of the waterway, creating a layer of orange sediment. In these situations, the iron oxide floc is only a temporary effect of the dam removal, not harmful to the environment, and will eventually be washed away by natural processes. As the waterway adjusts to its new, natural flow, the iron oxide floc will eventually disappear completely.
While the orange color may be surprising to see, it is a sign that the waterway is returning to a more natural state, leading to the water quality and habitat improvements achieved by dam removals. Removing outdated dams and restoring the natural flow of rivers has myriad benefits, including reconnecting river habitats that benefit fish and wildlife; reducing flood risk to surrounding communities; and promoting a healthier and more diverse ecosystem.
Princeton Hydro has designed, permitted, and overseen the removal of dozens of small and large dams throughout the Northeast. Click here to learn more about our dam engineering and removal services. And, if you're interested in reading about some of the dams we've removed in the Lehigh River Valley, click below:
According to American Rivers, “more than 90,000 dams in the country are no longer serving the purpose that they were built to provide decades or centuries ago.” As these dams age and decay, they can become public safety hazards, presenting a failure risk and flooding danger. Dams can also be environmental hazards, blocking the movement of fish and other aquatic species, inundating river habitat, impairing water quality, and altering the flow necessary to sustain river life.
Removing nonfunctional, outdated dams has myriad ecological benefits. Dam removal can improve water quality, restore a river back to its natural flowing state, reconnect river habitats that benefit fish and wildlife, and significantly increase biodiversity for the surrounding watershed.
For over a decade, Princeton Hydro has partnered with Wildlands Conservancy to remove dams in the Lehigh River Valley. Wildlands Conservancy, a nonprofit land trust in eastern Pennsylvania, works to restore degraded stream and wildlife habitat with a primary focus on Lehigh Valley and the Lehigh River watershed, which is a 1,345 square mile drainage area that eventually flows into the Delaware River.
Wildlands Conservancy contracted Princeton Hydro to design and permit the removal of two dams on the Little Lehigh Creek. Although it is referred to as the “Little Lehigh,” the 24-mile creek is the largest tributary of the Lehigh River. The dam removals restored the natural stream system, which hadn’t flowed freely in over a century.
Princeton Hydro also worked with Wildlands Conservancy to remove several barriers and three consecutive low-head dams on Jordan Creek, a tributary of the Little Lehigh Creek. Jordan Creek arises from a natural spring on Blue Mountain, and eventually joins the Little Lehigh in Allentown before flowing into the Lehigh River. It drains an area of 75.8 square miles.
Collectively, these dam and barrier removal projects on the Little Lehigh and Jordan Creek reconnected 15+ miles of river; restored fish passage; improved aquatic connectivity, fisheries, and benthic macroinvertebrate and wildlife habitats; reduced nonpoint source stormwater pollution; improved water quality; addressed vulnerable infrastructure; enhanced climate resiliency; and stabilized and restored the creeks’ channels and banks.
Building upon the successes of the Little Lehigh and Jordan Creek barrier removals, Princeton Hydro is again partnering with Wildlands Conservancy to remove three consecutive dams on Bushkill Creek in Easton, PA. The dam removal projects, which are slated for 2023, are part of a large-scale effort, involving a significant number of community and municipal partners, focused on restoring Bushkill Creek and the surrounding watershed.
The Bushkill Creek is a 22-mile long limestone stream that is designated as a “high quality, cold-water fishery.” It supports healthy populations of trout, and is treasured by anglers and the surrounding community as an important resource in an urban environment, spanning several boroughs and townships, eventually flowing into the Delaware River at Easton.
Environmental protection and restoration is a key goal of removing the dams. Removing these barriers will allow important migratory fish species to reach their spawning grounds once again, which has numerous and far-reaching ecological benefits. The project work also includes stabilizing the streambank, planting, and expanding riparian buffers, planting native trees and shrubs to filter runoff, and installing in-stream structures to restore fish habitat.
Princeton Hydro has designed, permitted, and overseen the reconstruction, repair, and removal of over 60 of small and large dams in the Northeast. To learn more about our fish passage and dam removal engineering services, click here. To learn more about Wildlands Conservancy, click here.
The Hudson River provides habitat for approximately 85% of New York State’s fish and wildlife species, 200 of which rely on the Hudson River for spawning, nursery, and forage habitat. According to Riverkeeper, a nonprofit focused on protecting and restoring the Hudson River, there are approximately 1,600 dams, mostly obsolete, fragmenting the rivers and streams of the Hudson Valley and blocking fish from reaching critical habitat.
The recent removal of two defunct dams – The Strooks Felt Dam and Furnace Brook Barrier #1 – marks an important milestone in the Riverkeeper’s journey to “Undam the Hudson River” and restore fish passage between the Hudson and the Atlantic Ocean.
The removal of these dams, located on tributaries of the Hudson River, are especially important to depleted populations of migratory fish like river herring and American eel, who are a vital part of the coastal ecosystem and spawn in freshwater tributaries.
Funding for both projects was provided by the Environmental Protection Fund and administered by the Department of Environmental Conservation (DEC). Riverkeeper led the effort to remove the obsolete dams, with Princeton Hydro providing dam and stream assessment, surveying, engineering design, and permitting assistance.
For the first time in 300 years, fish in the Quassaick Creek will be able to move upstream thanks to the dismantling of the 106-year-old, 4-foot-high Strooks Felt Dam in Newburgh, New York, located 60 miles north of New York City in the critical estuary of the Hudson River.
The dam site was dominated by gravel, cobble, boulder, and even bedrock steps, indicating a high-energy stream with a high sediment transport potential. This dam removal, like many others, released this coarse sediment and allowed the creek to carry it to downstream reaches. This coarse sediment forms habitat features like riffes, bars, and pools that are crucial components of healthy streams and rivers. Releasing the impounded bedload by removing these dams is key to increasing the resilience of freshwater streams like Quassaick Creek.
The dam removal, which was completed in October 2020, involved excavating the concrete spillway before reshaping and re-grading bedload sediment behind the dam.
Historically, the Strooks Felt Dam was part of a series of older dams that sat in slightly different positions in the same area and supplied former mill operations. Other nonobstructive structures associated with the former mill were left as part of an enduring history, allowing anyone who visits the site or combs through the records to visualize what was there before. The obsolete dam, however, will no longer block water, sediment, or critical fish passage.
Project collaborators included: Riverkeeper, Orange County and the City of Newburgh, the Town of New Windsor, DEC Hudson River Estuary Program, Quassaick Creek Watershed Alliance, Steelways Inc, RiverLogic Solutions, and Princeton Hydro.
Two additional dams farther upstream from the former Strooks Felt Dam site are in the early planning stages for removal.
The 5-foot-high, 75-foot-long Furnace Brook Barrier #1 was dismantled in Westchester County, New York in mid-November 2020. The removal of this dam brings migratory fish one-step closer to reconnecting with their ancestral habitat.
The positive results were immediate. Riverkeeper stated in a recently published article, “As soon as a path was cleared, we spotted two fish – white suckers, a freshwater species – darting up to the previously unreachable part of the brook. We can’t wait to come back in the spring and see whether herring, returning from the ocean, are migrating upstream…”
The dam clearing process at Furnace Brook involved the removal of the dam and an existing collapsed former concrete bridge span downstream of the dam. Stone masonry boulders from the former spillway were then redistributed and partially embedded in the restored channel to enhance aquatic habitat and increase bank stabilization.
Project collaborators included Rivekeeper, NYSDEC’s Hudson River Estuary Program, Westchester County Parks Department, Westchester County, the dam owner, the town of Cortlandt, the Friends of the McAndrews Estate, and Princeton Hydro.
Upstream of this project, Princeton Hydro is developing an initial engineering design and sediment management plan for the removal of another, larger dam.
Princeton Hydro has designed, permitted, and overseen the reconstruction, repair, and removal of dozens of small and large dams throughout the Northeast. To learn more about our dam engineering and removal services, visit: bit.ly/DamBarrier.
...
Highland Falls, New York, which is 40 miles north of Manhattan, stretches along the Hudson River and is populated by many lakes and ponds, including the Cragston Lakes (a.k.a. Lower Cragston). For the community’s 4,000 residents, living in an area where water is abundant has many benefits, but the benefits are not without flood risk.
The 9-acre Lower Cragston Lake, the second largest lake in the Highland Falls area, contains the Lower Cragston Dam, which is owned by the United States Military Academy at West Point and managed through the U.S. Army Corps of Engineers New York District (USACE NYD). According to the Office of the New York State Comptroller, Lower Cragston Dam is classified as a “High Hazard” dam. The dam is approximately 10 feet high and 210 feet long, and consists of an earthen embankment with a concrete core wall, a concrete ogee spillway, and a low level outlet.
In order to ensure safety to the surrounding community and mitigate any potential flood risk associated with the dam's operations, Princeton Hydro was contracted by the USACE NYD to perform an Engineering Assessment for Lower Cragston Dam. Engineering Assessments and periodic safety inspections are intended to provide an independent review of an existing dam structure to ensure that all components are functioning properly and in compliance with current dam safety regulations.
Princeton Hydro utilized a multidisciplinary approach to perform the Lower Cragston Dam Engineering Assessment, which consisted of:
The geotechnical investigation for the Lower Cragston Dam Engineering Assessment involved performing soil borings and rock coring within the dam embankment, for which Princeton Hydro developed a Drilling Program Plan (DPP) to ensure the activities were performed successfully and safely. The DPP, which also required our team to have a comprehensive understanding of bedrock and surficial geologic formations in the area, was ultimately approved by the USACE Dam Safety Officer and successfully executed in the field. The collected samples were tested at Princeton Hydro’s AASHTO-accredited and USACE-validated soil laboratory.
Ultimately, the geotechnical investigation and subsequent soil analysis were used to inform the slope stability and seepage analysis. The geotechnical analyses, hydrologic & hydraulic study, structural inspection, bathymetry, and dam break analysis were used to provide USACE and West Point with recommendations for repair options, replacement options, and decommissioning options for the dam.
Engineering Assessments are vital to the longevity of dams and the safety of the communities they protect. By providing detailed analysis, effective repair, and management programs can be designed and implemented efficiently. This helps to ensure dam systems are providing the level of protection they were designed to deliver.
Princeton Hydro has designed, permitted, and overseen the reconstruction, repair, and removal of dozens of small and large dams. Our Geoscience and Water Resources Engineering teams perform dam inspections and conduct dam feasibility studies throughout the Northeast. For more info, click here.
…
For over 100 years, the Old Mill Pond Dam in Spring Lake Heights, New Jersey has blocked critical anadromous fish species from reaching optimal spawning habitat. Today, we are thrilled to announce that, thanks to a fish ladder installed by the American Littoral Society (ALS), migratory fish can now scale the dam and access upstream spawning grounds.
The 60-foot-long fish ladder is a device that allows a channel of water to flow through it and is engineered to create both the proper water depth and velocity for fish to navigate through. In this case, it will enable fish to scale the 10-foot-high dam and go deeper into Wreck Pond Brook.
This video from ALS provides an up-close look at the Alaska-Steeppass Fish Ladder and more details about the project:
Re-opening river passage for migratory species improves not only the health of Wreck Pond Brook and its watershed, but it also benefits the overall ecosystem of the Atlantic shoreline and its coastal rivers. It also supports important recreational and commercial species, such as cod, haddock, and striped bass, which leads to a healthier economy.
For over a century, the dam blocked anadromous fish like Alewife and Blueback river herring, from entering the Wreck Pond Brook Watershed. These fish spend most of their lives in the ocean but need freshwater in order to spawn. The Old Mill Pond Dam, an impassable obstruction for these migrating fish, was identified as a key contributor to the decline of Atlantic coast river herring populations. Subsequently, river herring were classified as National Oceanic and Atmospheric Administration (NOAA) Species of Special Concern and identified as requiring Concentrated Conservation Actions.
The fish ladder, which was funded through the US Fish and Wildlife Service and implemented by ALS along with a variety of project partners, including Princeton Hydro, is one more major step in the ongoing effort to restore critical migratory fish spawning grounds, support a vibrant food web to the area, and rehabilitate Wreck Pond and its watershed.
According to the ALS, “Now, instead of Old Mill Dam acting as the furthest migration destination for Alewife and Blueback river herring, these fish have the ability to navigate up the dam through the fish ladder and utilize roughly an additional mile of optimal spawning habitat. The ALS will add the Old Mill Dam fish ladder and newly accessible spawning habitat into its ongoing river herring monitoring surveys.”
American Littoral Society promotes the study and conservation of marine life and habitat, protects the coast from harm, and empowers others to do the same. Learn more and get involved: littoralsociety.org.
Princeton Hydro has designed, permitted, and overseen solutions for fish passage including the installation of technical and nature-like fishways and the removal of dozens of small and large dams throughout the Northeast. To learn more about our fish passage and dam removal engineering services, visit: bit.ly/DamBarrier.
Images provided by the American Littoral Society.
Your Full Name * Phone Number * Your Email * Organization Address Message *
By EmailBy Phone
Submit
Δ
Couldn’t find a match? Check back often as we post new positions throughout the year.
PRINCETON HYDRO
PRINCETON HYDRO